Automatic weighing machine and feed control means therefor



L. W. ALDRIDGE AUTOMATIC WEIGHING MACHINE AND FEED CONTROL MEANS THLREFOR Jan. 20, 1953 9 Sheets-Sheet l Filed June 2l, 1948 Jan. 20, 1953 L. w. ALDRIDGE AUTOMATIC WEIGHING MACHINE AND FEED CONTROL MEANS THEREF'OR 9 Sheets-Sheet 2 Filed June 2l, 1948 jan. 20, 1953 L w, ALDRIDGE 2,625,042

AUTOMATIC WEIGHING MACHINE AND FEED CONTROL MEANS THEREFOR 9 Sheets-Sheet 5 Filed June 2l, 1948 2 A. \i\|.\\\ W M m VI R qw f Mm, m I| i M Y 1 G ,Y m E.-

l mma Q w M D k N m E N n- 9.n wm @mw n. IQ mM s E R www s R N mmm w Qn Mu NJ Am@ www .u uv A mm Jan. 20, 1953 Flled June 21 1948 Jan. 20, 1953 l.. w. ALDRIDGE 2,625,042

AUTOMATIC WEIGHING MACHINE AND FEED CONTROL MEANS THEREFOR Filed June 2l, 1948 9 Sheets-Sheet 5 f fr@ 5M f www J www :imam/bom 9 Sheets-Shree?l 6 lmf/el'll'id e www Jan. 20, 1953 w. ALDRIDGE AUTOMATIC WEIGHING MACHINE AND FEED CONTROL MEANS THEREFOR Elled June 2l, 1948 Jan. 20, 1953 w, ALDRlDGE 2,625,042

AUTOMATIC WEIGHING MACHINE AND FEED CONTROL MEANS THEREFOR Filed June 2l, 1948 9 Sheets-Sheet 8 jmwwa @www Jan. 20, 1953 L. w. ALDRIDGE 2,525,042

AUTOMATIC WEIGHING MACHINE AND FEED CONTROL MEANS THEREFOR Filed June 2l, 1948 9 Sheets-Sheet 9 JWM Patented Jan. 20, 1953 F F I CE AUTOMATEC WEIGHING li/IACHNE ANB FEED CONTROL MEANS THEREFR Luther W. Aldridge, Durham, N. C., assign-or to Wright Machinery Company, Durham, N. C., a corporation of North Carolina Application .lune 2l, 134%, Serial No. MJS?,

(Ci. MSW-229) i Claims. 1

The present invention relates to an automatic weighing machine and to automatic neans for continuously feeding material to be weighed to said weighing machine.

More specically, the invention relates to novel material feeding means particularly adapted to feed material to be weighed to an automatic weighing machine of the kind disclosed in the oopending application of Glen M. Tracy, Serial No. 659,263. However, it is to be understood that the material feeding means disclosed herein is not necessarily limited to use with any particular kind ol weighing machine.

The material feeding means comprises vibrating dribble and bulk feed conveyors having the feed troughs thereof arranged in superimposed relation, with the dribble feed trough disposed above the bulk feed trough. Both troughs are arranged to simultaneously discharge material into a receiver o weighing bucket on the Weighing machine est.. just prior to the making of the desired weight. Means responsive to the weight of the material deposited in the receiver or bucket by both conveyors is adapted to automatically interrupt operation of the bulk feed vibrator when the material in the bucket closely approaches 'the desired weight. The dribble feed vibrator, however, operates continuously and the dribble feed trough continues to discharge material into the bucket until the exact desired weight has been made whereupon two baffle plates, interposed between the weighing bucket and the discharge ends of the vibrating troughs, are automatically actuated to a position wherein they form a temporary hopper for collecting the material which continues to be fed by the dribble fee trough.

The weighing machine disclosed herein, by way of illustration and not limitation, includes a carriage which is automatically shifted, after closing of the hopper, by mechanism actuated in response to e. predetermined downward movement of a movable member of the weigher caused by the making of the exact desired Weight. Means is also provided to lift or elevate the loaded bucket off the weigher prior to the shifting of the carriage and such lifting enables the movable inember of the weigher to return toward the position it occupied at the beginning of the weighing operation. This return movement restarts the bulk feed vibrator and it begins to feed material into the closed temporary hopper. The shifting of the carriage then quickly moves the loaded bucket `to a dumping position and moves an empty bucket into loading position. The bams plates are then returned to their initial open position and .le material which has meanwhile collected in the temporary hopper is discharged into the empty receiver or bucket, and the weighing cycle is rei peated. The speed of operation of the bucket elevating and carriage shifting means is 4so rapid that excess of material is never fed into the tesiporary hopper.

dribble feed trough is shallow, arcuate in cross-section, and gradually tapers or becomes narrower toward its discharge end, so that its cross-sectional area progressively decreases tcward said end, thereby assuring a continuous feed of articles in single file, or the delivery of a continuous ne stream of substantially constant volume. This feature is quite impor because it makes possible very accurate weig.. at high speed. rhe shallowness and gradual narrowing of the dribble feed trough provide a choking effect which causes some of the excess material introduced into the receiving end of said trough to overflow or pass over either side of the dribble feed trough and into the bulk feed trough before said excess material reaches the discharge rf of said dribble feed trough. The gradual taperng or narrowing of the dribble feed trough toward its discharge end assures a continuous and uniform discharge inasmuch as the volume of material discharged is less than that which is normally introduced into the relatively wide receiving end of said trough. Hence, during normal operation, excess material deposited in the dribble feed trough will spill over onto the bulk feed trough to be discharged along with whatever material has otherwise been introduced into the bulk feed trough.

In the present construction, the dribble feed trough is carried by the bottom wall of a vibrating hopper and in effect forms a continuation of said hopper. The vibrating hopper is much greater in width than the receiving end of the dribble feed trough, but of only slightly less width than the bulk feed trough. The receiving end of the bulk feed trough extends to a point beneath the discharge end of the vibrating hopper and gates are adjustably mounted upon the side walls of said hopper to regulate or vary the volume of material that can be fed directly by the hopper into the bulk feed trough.

In the complete machine disclosed herein, the material to be weighed is fed by an electric motor driven endless feed belt conveyor, whose operation is automatically controlled by a feed control device interposed between the discharge end of conveyor and the vibrating hopper, which simultaneously feeds material to the bulk and dribble troughs. The feed control device comprises an inclined, pivotally mounted chute which is operable to automatically open a normally closed switch controlling the motor which drives the feed conveyor, to thereby stop said feed conveyor whenever material in excess of a predetermined weight has been deposited in said chute and has caused the discharge end thereof to move downwardly toward the bottom wall of the vibrating hopper. This prevents too rapid feeding of material to the vibrating hopper. The

feed control device is further arranged so that as the excess material is advanced by the vibrating hopper, the chute is tilted in a manner to raise its discharge end, so that the switch controlling the conveyor drive motor is permitted to close to start the motor and restore operation of the feed conveyor. In this manner, a continuous supply of material to the dribble and bull; feed troughs is assured, without danger of spilling and wasting the material to be weighed, and without requiring the machine operator to constantly observe and adjust feed conditions.

ln another form of the machine, the dribble feed is operated intermittently, that is to say, its operation is automatically stopped or interrupted when the desired exact weight is made. 1n such machine, the baille plates forming the temporary hopper and the actuating mechanism therefor are unnecessary and can be eliminated.

The principal object of the invention is to provide an automatic weighing machine that will operate rapidly and with great accuracy.

Another object of the invention is to provide an automatic weighing machine having means for automatically controlling the feeding of the material to be weighed to the receiver or bucket of the Weighing machine.

Another object of the invention is to provide a relatively simple feed control device adapted to be interposed between two conveyors and which device will automatically control the operation of one conveyor so as to prevent the same from feeding an excess of material to the other conveyor.

Another object of the invention is to provide an accurate automatic Weighing machine including dribble and bulk feed vibrating conveyors wherein the bull; feed is operated intermittently and the dribble feed operates continuously, and wherein the bulk feed is restarted to deposit material in a temporary hopper along with the dribble feed Vwhile a loaded bucket is being dumped, in order to effect a maximum output of the weighing machine. l

Another object of the invention is to provide a simplified weighing machine in which the operation of the dribble feed is also interrupted (after the desired weight has been made), thereby making it possible to omit the temporary hopper for intercepting and collecting the dribble feed.

Another object of the invention is to provide material feeding means including a vibrating hopper arranged to simultaneously supply material to dribble and bulk feed troughs.

Still another object of the invention is to provide means for simultaneously feeding bulk and dribble feed conveyors whereby the relative volume of material fed to the bull; conveyor can be varied in accordance with differences in weighing requirements.

A further object of the invention is to provide a dribble feed trough which is so shaped and constructed that it will continuously feed articles in single iile or deliver a continuous fine stream of substantially constant volume.

A still further object of the invention is to provide independently operable vibrating feed conveyors having the operating mechanism therefor arranged in tandem, so that the vibrat ing troughs are disposed in superimposed relation and thus occupy a minimum of space.

Other objects and advantages of the invention will be apparent from the following description taken in conjunction with' the accompanying drawings, in which: y

Fig. l is a diagrammatic view, partly in crosssection, showing the correlation of the feed conveyor, the automatic feed control chute, the vibrating dribble and bulk conveyors, the weigher, and the various circuits for the automatic control of the complete Weighing machine;

Fig. 2 is a side elevational view of a portion of the feed conveyor, the feed control chute, the vibrating dribble and bulk conveyors, and the means for maintaining the feed control chute in a predetermined position so that the lower end thereof is maintained in spaced relation to the bottom of the feed hopper of the vibrating conveyors until material in excess of a predetermined weight has been deposited in said chute by said feed conveyor;

Fig. 3 is an enlarged elevational view of a portion of the other side of the feed conveyor and feed control chute, and particularly illustrating the switch which is actuated by tilting movement of therfeed control chute for controlling the operation of the motor that drives the feed conveyor;

Fig. 4 is a plan view of that portion of the machine which is shown in Fig. 2, with the upper shaft of the feed conveyor shown in dot-and-dasli lines;

Fig. 5 is a sectional View through the vibrating hopper, dribble feed trough and bulk feed trough, taken on the line 5--5 of Fig. ll;

Fig. 6 is an enlarged end View of the vibrating hopper, and dribble and bulk feed troughs, as viewed along the line 6--5 of Fig. 5;

Fig. '7 is a side elevational view of the mechanism employed for actuating the baiiie plates to form the temporary hopper, and the mechanism for lifting a loaded bucket off the weigher;

Fig. 8 is a vertical sectional view taken on the line @-3 of Fig. 7;

Fig. 9 is a vertical sectional view taken on the line 9-9 of Fig. 8, but illustrating the bailes in their closed, hopper-forming positions;

Fig. 10 is a fragmentary plan view of a portion of the mechanism shown in Fig. 7, but with the baffles shown in their closed position corresponding to Fig. 9;

Fig. ll is an elevation-al View somewhat diagrammatically illustrating the mechanisms for effecting elevation, transfer', and dumping of weighing buckets, but omitting in the interest of clarity, the baille supporting and operating mechanism shown in Fig. '7

Fig. l2 is a detail plan view illustrating the manner in which the bucket elevating b-u rs are guided by the two pairs of cams which raise the buckets into a position to be received by tie elevating bars and lowered onto the movable member or yoke of the weighing machine;

Fig. 13 is a fragmentary schematic iew illusM trating a modification wherein the opera-tiener" the bulk feed conveyor and the dribble feed conveyor is interrupted in succession and remain inactive while a loaded bucket is being dumped; and

Figs. le and l5 diagrammatically illustrate mechanism for elevating and dumping the weigh er bucket shown in Fig. i3.

Referring now to Fig. l of the drawings, numeral l5 generally identifies a feed conveyor including aninclined, endless belt i6, the upper portion Vof which passes around a pulley il mounted upon a shaft IS, and the lower portion of which passes around a pulley it mounted upon a shaft 2d. The shaft 2li also has a pulley 2i mounted thereon which is driven by a Vpulley EZ through a belt The pulley 22 is mounted upon the shaft 2li of an electric motor 25. The shaft i3 has one end thereof mounted in an adjustable support 2S (Fig. 2) and the other end thereof is mounted in a similar support 2l (Fig. 3). The adjustable support 2t includes a threaded shank'. 23, which extends through a block 2d welded cr otherwise secured to an angle iron forming part of a housing Si for the conveyor belt lli. The shank 28 is adapted to be adjusted longitudinally relative to the block 2S and to be xed in a desired position of adjustment by nuts i2 engaging the opposite sides of said block. Sill iiarly, the support 2'! includes a threaded shank extending through a block Zd velded or otherwise secured to an angle iron member di?, the shank being adjustable relative to the block 29 by nuts du. The shaft 2d is mounted in similar adjustable supports (not shown). rlhus, the dosired tension in the feed conveyor belt it can be maintained by suitable adjustment of the aforesaid supports.

The conveyor housing Si may be of any conventional or suitable construction and includes a side wall 33 (Fig. 2) having a segment-shaped cheek plate Sei spot-welded thereto, as indicated at 35. rihe conveyor housing Si also includes a side wall tt (Fig. 3) having a somewhat similar cheek plate il spot-welded thereto, as indicated at 3S. The cheek plates 3d and are disposed close to the sides of the conveyor belt i6 and serve as guides for the material discharged from said belt, as will be most clear from Fig. e.

One end of a strip 3i! (Figs. 2 and is secured 't0 the angle iron 3d by bolts @ne end or a siinilar strip di (Figs. 3 and 4.-) is secured to the angle iron du y bolts rihe strips and di pivotally support a shaft t3 to which balance plate or feed control chute :is is welded, braced or otherwise i'lXedly secured. The chute :it is wide enough to receive the free ends or" the cheek plates 3d and Si the ein, so that said plates guide material from the feed belt IG into said chute. The chute ftd is normally inclined downwardly and the shaft t3 is secured to the bottom wall 45 of said chute at a point adjacent the upper end thereof, One end of the shaft is reduced in diameter, as indicated at (Figs. 2 and e), and one end ci an arm fil' is and secured thereto by a cap screw d3. The opposite end oi the arm d? is connected to one end of a tension spring lid and the opposite end of said tension spring is connectedl to a threaded rneniber 5@ adjustably secured to a bracket 5! by nuts The bracket 5i is riveted at 53 to an argile iron brace which turn is secured to ie conveyor' housing Si by one or more bolts The other end oi the shaft d3 is also reduced, y.s indicated at (Figs. 3 4), and has the plit end of an arm secured thereto by a cap row The upper side of the other end of is adapted. to engage with the end of .ble stop threadedly mounted in a A lock nut 6I is from the foregoing that acting on the shaft d3 that rotation or" the shaft d4 fixedly secured to said by the engagement of the arm 51 t r1 Thus, the position of the lower end of the chute 4s relative to the bottom wall 62 of a vibrating hopper $3, which will be described in further detail later, can be varied as desired by adjustment of the stop 59, and the weight of material required to overcor.e the tension of the spring E9 to eifect downward tilting of the chute lid can be varied by adjusting the tension of said spring di).

The strip 4i (Fig. 3) has a brac et @d sccured thereto by two screws 6d. The bracket 64 has a conventional, normally closed Micro switch 66 mounted thereon by a pair or bolts S7. The "Micro switc includes the usual operating pin or plunger 63 actuated through a spring arm 59 carrying a roller il. The roller is positioned so that it is engaged by the underside of the arm 5l.

It will be apparent fron the foregoing, that when the tension of the spring i9 is overcome by an excess weight of material delivered to the chute 44 by the feed conveyor l5, the lower end M' of said chute will move downwardly into engagement with the bottom wall G2 of the hopper E3 and in so doing the arm El engaged with the roller 'Hl of the Micro switch 85 will cause said switch, upon the downward actuation oi plunger 68, to open. One contact (not shown) of the switch S6 is connected by a wire 'ii (Fig, l) to one side of the electric motor 25 and the other side of said motor is connected by a wire l2 to a conductor i3. The other contact (not shown) of the switch 555 is connected by a wire 'ifi with a conductor i5. It will be obvious, thereore, that whenever the chute d4 is loaded with a weight of material in excess of that for which the spring i9 has been set, the trough will tilt or pivot about the axis of the shalt in a downward direction to effect opening or" the switch E to thereby interrupt the circuit to the motor 25 and thus stop the driving of the feed belt IS. It will also be apparent that, upon removal of the excess material from the hopper 53, the spring iii will tilt the chute upwardly and raise the lower end of said chute to its normal position with the arm 5i engaging the stop 59. The latter tilting movement will remove the pressure on the roller 'fil and spring arrn 68, and the switch 66 will be allowed to close and restore the circuit to the motor whereby to restart driving of the feed belt IG to supply addiu tional material to the hopper $3 through the trough lid. Thus, the supply of material to the hopper 63 is automatically controlled at all tinies to prevent spilling and wasting of the material to be weighed.

Referring now to Figs. l, 2 and 5, the bottoni wall 62 of the hopper E3 carries a plate l which is mounted upon a spring frame i? of a conventional vibrator unit 'i3 including a magnetic coil. i9 and an armature 'which is attracted therem by for imparting rapid vibration to the frame 1?, in a manner well understood in the art. The vibrating unit i3 is spring-mounted upon a base Si secured to a platform t?. (Fig. 2) supported by a vertical column e3. The column r2.3 has an adjustable bracket 8d mounted thereon, which is welded cr otherwise secured to the brace 5d and thus serves as a support for the upper portion or the conveyor housing 3i The hopper (i3 includes side walls and adapted. to receive the lower end or" the chute i therebetwee; The walls and are con neste-d by a wall which underlies is spaced from the chute The discharge end of the bottom wall 2 includes portions SS which converge forwardly and terminate in a straight end portion 89, as best illustrated in Fig. 4. A dribble trough Se, which gradually tapers or becomes narrower in a direction away from the end 89 ofthe bottom wall 62, is welded or otherwise suitably secured to the underside of said bottom wall. The dribble trough Sii is shallow and arcuate in transverse cross-section, as is best shown in Fig. 6, and the area within the trough progressively decreases toward its discharge end. The extremity 89 of the bottom wall b2 carries a flange 92 extending downwardly into the dribble trough 90 for preventing material discharged from said bottom wall into said dribble trough from working its way back under said bottom wall.

A bulk feed conveyor including a trough @3 is disposed below the dribble feed trough Si) and extends part way under the bottom wall t2 of the hopper 63. The bulk feed trough 93 has a bottom wall Sd whichris mounted upon a spring frame 95 of a conventional vibrator unit Si? similar to the unit 1S. The vibrator unit is also spring-supported upon the base 8l and the vibrators i8 and $6 are arranged in tandem. The bulk feed trough 93 includes side walls el which are disposed outwardly of the hopper side walls S and 85. than the side walls 9i interconnects said side walls.

The discharge end SE-S-e of the bottom wall t2 of the vibrating hopper 63 overlies the bottom wall 94 of the bulk feed trough $3, so that when the hopper 63 is rapidly vibrated, material is simultaneously fed over the end of said bottom wall B2 into the dribble feed trough @t and into the bulk feed trough S3. dribble feed trough is arranged centrally of the bulk feed trough 93 and forms, in effect, a continuation of the vibrating hopper $3. The relative amount of material fed to the bulk feed trough 93 can be regulated by the adjustment of a pair of gates 99, one of which is carried by each of the hopper side walls 85 and e5. A bracket Itri is secured to each of the hopper side walls Se and 86 and a wing bolt itl is threaded into each of said brackets and is arranged to clamp the gates 9S in any desired angular position relative to the hopper side walls 85 and 85.

When the vibrator units 'i8 and :3B are in operation, the material to be weighed is simultaneously moved toward the discharge ends of the dribble and bulk feed troughs 99 and 93, respectively, and discharged into a receiver or Weighing bucket lElZ. Inasmuch as the dribble feed trough 9i) becomes narrower toward its discharge end, the excess material conveyed thereby is forced over either side thereof by the choking action of the trough and flows into the bulk feed trough, as indicated by the arrows in Fig. e, so that eventually a single-file article feed or a very ne stream is discharged from the dribble trough. The material thus added to the bulk feed trough 93 is fed along with the material previously introduced thereintc by the vibrating hopper E3.

The bulk and dribble troughs 93 and @il feed a weigher including the weighing bucket l G2 (Figs. l and l1) which is mounted upon a carriage IEB in side-by-side relation to a similar bucket Il'ifl. Each of the buckets H32 and IIE-d is provided with trunnions IE at the opposite ends thereof, and these trunnions are received in open slots m6 formed in the sides of the carriage ISS. The bucket H32 is illustrated in full lines in its loading position in Fig. 1, with the trunnions IE5 thereof A rear wall S3 of less heightV 8 supported upon the ends of a yoke IDI, and the bucket its is shown in a position to which it has been moved by the carriage ISS to effect dumping thereof. The bucket Il2 is represented in its dumping position by dot-and-dash lines. The carriage Ii3 is adapted to be automatically reciprocated to empty a loaded bucket and to place an empty bucket in loading position, by a carriage shifting mechanism which will be briefly described hereinafter. This carriage shifting and dumping mechanism is disclosed in more complete detail in the copending application of Tracy, Serial No. 659,263, supra.

The yoke I ll'l is part of a buoyant or liquid displacement type of weighing mechanism IDB, which is diagramma-tically illustrated in crosssection in Fig. 1.. The yoke 'i is mounted upon the upper end of a rod H39, which has a cross bar il@ secured to the lower end thereof. The rod IQ is guided for vertical movement by rollers I il mounted upon a bracket I I2 disposed within a container i I3. The container H3 is partially filled with oil or other suitable liquid IIli, and a pair of hollow floats H5 is'buoyantly supported by the liquid Ile, the lower ends of said floats being pivotally connected to the outer ends of the cross bar Il. Stop pins IIS are mounted upon the bracket H2 and maintain the rloats l I5 sub merged in the liquid I I A to a predetermined depth such that the floats I I5 displace a volume of the liquid I l@ equal to the weight of the material to be weighed in one of the buckets m2 and l, plus such additional volume of liquid as is necessary to compensate for the dead weight of the empty bucket, rod IM, yoke it?, etc. Thus, the oats H5 are preloaded and will not begin to move downwardly in the liquid I Ill until a predetermined weight of material has been deposited in the weighing bucket supported by the yoke l0?. If the desired weight to be made is one pound. for example, then the liquid level is adjusted so that the rod les does not begin to move downwardly until the material deposited in the bucket being loaded is within an ounce or two of said desired weight.

The container H3 has a cover ill upon which normally open Micro switch H8 is mounted. A bracket I Iii is mounted upon the Micro switch M5 and pivotally supports a lever IZil. One end of the lever 23 engages the usual operating pin E25 of the Micro switch I i8, and the other end of said lever is adapted to be engaged by a pin I22 carried by the rod its. rThe pin IEE is normally held in engagement with the lever I2@ by the buoyant effect of the liquid IId upon the floats l i5, so long as there is less than a predetermined weight of material in the weighing bucket supported by the yoke ili. However, when the weight of the material in the bucket being loaded closely approaches the desired maximum, i. e., is within an ounce or two of the desired weight, the buoyant effect of the liquid on the floats H5 is overcome and the loaded bucket, yoke H31, and rod it@ start to move downwardly displacing some of the liquid I ld and thereby relieving the pressure of the pin I?? on the lever 2li and permitting the switch i I S to open and discontinue operation 'fhe bulk feed conveyor as will now be explained. rFhe rheostats E23, 35 can vary the speed of vibrators '58,' 95.

One contact (not shown) of the switch H8 is connected by a wire 23 to one "side of the bulk vibrator unit 96 and the other side of said unit is connected by a wire I24 to one contact of a conventional rectifier |25. The other contact (not shown) of the switch i8 is connected by a wire I2@ to the arm |21 of a conventional rheostat |23. The rheostat |28 is connected by a wire |253 to another contact or the rectifier and the rectifier |25 is connected with the conductors 13 and 15, respectively, by wires |393 and 53|. Accordingly, when the switch it is permitted to open, the circuit to the buik vibrator t will be interrupted and the feed of material by the bulk feed conveyor 93 will be discontinued. rli'he operation of the dribble feed vibrator .v, however, is not interrupted and it continues to ieed material to the nearly fully loaded buclet on the Weigher |68, displacing more liquid iid until the exact desired weight has been made. in this connection, it will be noted that one side of the dribble feed vibrator 18 is connected by a wire |32 to one side of a conventional rectifier |33 and that the other side of said vibrator is connected by a wire |34 with the arm oi a conventional rheostat |36. The rheostat i3@ is connected by a Wire |31 with another contact ci the rectiiier |33 and wires |38 and |39 connect the rectiiier |33 with the conductors i3 respectively. The supply of current to the conductors 13 and i5 is controlled by manuaiiy operable 'main switch |45.

The material deposited in the bucket by the dribble feed conveyor trough ai?, after the operation o the bulk feed trough 93 has been discontinued, to complete the desired weight, necessarily produces a slight further downward movement or the yoke |01 and rod ids. Such further movement is utilized to operate a second y switch comprising a U-shaped conductor Eii (Fig. l) carried by an insulating block iii mounted upon the rod |09, and an insulating block |553 mounted upon the cover ||1 and containing two mercury pools |44 and |45 adapted to be engaged by the legs of the U-shaped conductor itl as the rod |09 is moved downwardly to thus electrically interconnect said mercury pools. The mercury pool Me is connected by a wire il-ief to one side or" a solenoid Hi? the mercury pool |65 is connected with the conductor The other side oi the soienoid ist connected with the conductor to c plete the circuit. An armature |58 has one end thereof pivotally mounted upon the housing or the solenoid bi1 and its other end is adapted to lie the path of an arm |49 carried by the driven eieinent i5@ of a one-revolution, slip-type tion clutch |5'|. The clutch element is mounted upon a shaft |52 and is frictionaly engaged by a continuously rotating driv clutch element |53. The driving element is secured to a shaft I5!! having a gear secured thereto and continuously driven by a gear E which derives its rotation from a motor rThe motor iba operates continuously and connected by wires |5610 and |55c with the conductors 13 and 15, respectively. The clutch |51 slips when the part |5|| is held stationary'by the armature MS.

The shait |52 serves as a source of power for driving mechanism for elevating a loaded bucket from the weigher |08 and for erecting shifting of the carriage |3, as will be described later, and also as a drive for `eiiecting operation ci baiiie plates |51 and |51@ adapted to be actuated from the open position shown in iull lines in Figs. l and 2, to a closed position shown by the dot-anddash lines in Fig. 2, to form a temporary hopper |53 adapted to catch the material which continues to be fed by the dribble feed trough 9|) While the loaded bucket |532 is being transferred to the dumping position indicated by dot-and-dash lines in Fig. l and the empty bucket ist is being righted and returned to its loading position. lThus, when the electromagnet iili is energized by the closing oi the switch Mii, 542i, m5 its armature |45 is moved out or the path of the arm U39, thereby releasing the driven eiement |56 of the one-revolution ciutch |5| permitting the shaft |52 to be turned through one revolution. Upon raising ci the ioaded bucket It from the weigher yoke |91, as will be explained later, the floats H5, being reiieved of the weight of the loaded bucket, move the rod mi) upwardly, thereb-y raising the U- shaped contact member |4| out of the mercury pools its and M5 to effect deenergization of the solenoid M1, whereupon the armature |53 again assumes a position in the path of the arm |235 and interrupts the rotation of the driven clutch element |56 after it has made one revolution. rhe raising of the rod |69 also brings the pin into contact with the lever |29 so that said iever is caused to pivot and actuate the switch lic to its closed position, thereby restoring the circuit to the bulk vibra-tor to restart the feeding oi material by the bulk feed trough d5 while baffle plates |51' and |5|a are still in closed position. Arter the empty bucket has been positoned on the weigher yoke Ibi, the barde plates |51 and iia are reactuated to return them to their open positions to discharge material rn the temporary hopper momentariiy ioiined thereby into the empty bucket.

The details of construction of the baille plates i5? and |51a and the mechanism for actuating the same are best illustrated in Figs. 'l to 1), 1nclusive, to which reference now may be had.

The bafe plate |51 is secured to a flat por-- tion oi a shaft |59 by rivets its and the baite plate |51EL is similarly secured to a nat portion of a shaft lei by rivets IEE. The baflie plate i5? has side extensions |53, which are cooperable with similar side extensions it@ on the baffle plate |51a to provide the temporary hopper |555 when the baiile plates are actuated to their closed position. The side extensions |54 are adapted to be disposed between the side extensions |33, whereby to form side walls for the hopper |53, the baille plates |51 and |51a themselves being adapted kto form the bottom of said hopper. A strip of rubber or .other suitable flexible material it is carried by and forms an extension of the baffle plate |51 and a similar strip |65 is carried by and forms an extension of the baiile plate iii'i. An arm |151 is secured by rivets |38 to each of the side extensions |63 or" the baiiie plate i5? and in turn is secured by a pin it@ to the shaft |59. Similar arms l1@ are secured by rivets i'i'i to the side extensions |54 of the baffle plate 51a and are secured by pins |12 to the shaft mi.

The shaft |59 is rotatably supported in brackets |13 secured to rails |14 by cap screws |15. The

it secured to the rails |1=1 by cap screws iii. The rails secured to the upper ends of 'or cirets fil Each of the rollers `|84 is provided with a groove |85 to enable the same to serve as a guide for the lower end |87 of a vertically reciprocable yoke |88. The upper portion |89 of the yoke |88 resembles an inverted triangle and a gear rack |95 is secured by cap screws |E|| to the inner side of the yoke |88 at the opposite ends of the base or uppermost portion of said triangle. The teeth of each of the gear racks |95 mesh with the teeth of gears |92. The gears |532 are disposed between discs .|93 and |53a on either side thereof, said discs and each gear being secured together by screws |93b, and each disc |532L being secured to its respective shaft |59 and by a pin ISSC. The teeth of the gear racks |55 thus ride between the discs |53 and |5532, and said discs thus serve as guides for the upper end of the yoke |88.

The lower yoke end |87 carries a roller |513 (Figs. 7 and 8), which rides in a groove |55 formed in a baffle-operating face cam ist secured to a shaft |97. The shaft |57 is intermittently driven through a single revolution from the shaft |52 (Fig. 1) by suitable intermediate mechanism (not shown), and one end of the shaft |57 is journalled in a bushing |55 mounted in one of the side plates |335. It will be apparent from the shape of the cam groove |95 (Fig. '7) that, as the cam |96 is rotated, it will effect up and down movement of the yoke |38. Zit will also be apparent that, as the yoke |33 is raised, the gear racks |95 acting through the gears |92 will effect rotation of the shafts |59 and ISI through an angle such that the baifle plates |57 and |57a will assume the position illustrated in Fig. 9, with the flexible portions |55 and |66 thereof in engagement. l'ihe iiexible strips |55 and |55 thereof in engagement. rThe flexible strips |65 and |66 prevent damage to the baffle plates |57 and |578, which might otherwise occur when a hard object is caught therebetween in mid-air, during closing movement of said plates. The timing .is such that the first forty degrees of rotation after tripping of the onerevolution clutch |5| effects closing of the baie plates |57 and |57a. When the baffle plates |57 and |57a are in their closed or raised position they form the bottom walls of the hopper |58 which receives the material that continues to be fed, after the desired weight has been made, by the dribble feed conveyor trough 90. Of course, as the yoke |83 is lowered by the cam |95, the baffie plates |57 and |572L will be restored to their open position shown in Fig. '7 and the material accumulated in said hopper drops into the empty bucket |52.

One end of a tension spring |95 is connected by a cotter pin 230 with an intermediate portion of the yoke |88, and the opposite end of said spring is connected to the upper end of a stud 28| which has its lower end threaded into one of the side rails v|75 and locked against rotation by a jam nut 2i2. rIhe action of the tension spring |99 tends to raise the yoke |83 as permitted by the shape of the cam groove |55 and relieves the cam |96 of the weight of said yoke. It will be observed that Fig. '7 shows the cam |95 in a position wherein tne baffle plates |57 and |57a are almost in their fully open position. It will also be observed that the cam groove |55 includes a concentric portion 253 of substantial arcuate length adapted to maintain the baie plates |57 and |57a in their closed position for a considerable portion of the time that the shaft |97 is making a single revolution. It

l2 is while the baiiies |57 and |57a are in their closed position that shifting of the carriage |53 is effected by mechanism which will now be de scribed.

Referring to Figs. 8 and 11, the carriage |83 is provided with rollers 254, which ride in grooves 25de formed in the inner faces of the rails |75. The rails |723 are each provided with an elongated slot 235 (Fig. 1l) and studs 255 secured to op posite sides of the carriage |53 extend through said slots. An arm 257 at each side of the inachine has a slot 208 at the upper end thereof in which the stud 256 is received. The arms 257 are secured to a shaft 2te which extends across the machine and is carried by brackets 2 i5. One end of a lever Zilla is secured to one end of the shaft 25e and the opposite end of said lever is .connected to one end of a link 2|| by a pin 2| |21. rihe opposite end of the link 2|| is connected by a pin 2| Ib to a crank 2 2 mounted upon a shaft 2|3. The shaft 2|3 is driven from the one-revolution shaft |52 by intermediate mechanism (not shown) designed so that the shaft 2 i3 is rotated only one-half of a revolution for each full revolution of the shaft |52. Hence, as the shaft 2 |3 is rotated through a half revolution, the crank 2 |2 will cause the upper end of the arms 25| to be moved from the position adjacent one end of the slot 255 to a position adjacent the other end of said slot, thereby moving or shifting the carriage les a distance sufficient to transfer the bucket ital from its loading position shown in Fig. 11 to its dumping position shown in Fig. 1. The timing and design of the aforedescribed carriage shifting mechanism is such that the shaft 2|3 rotates intermittently and in timed relation to the baiile plate operating shaft |97.

As the loaded bucket Idil is moved toward the left, as viewed in Fig. 11, a pin 2 L. carried by said bucket engages guide rails 2|5 for automatically tiltingthe bucket |52 to dumping position while the carriage H33 is still in motion. The movement of the carriage |53 to transfer the loaded bucket |52 to dumping position simultaneously moves the empty bucket |52 into loading position.

Rails 2|E similar to the rails 2|5 cooperate with a pin 2H carried by the bucket |52 for effecting righting of said bucket as it is moved by the carriage |93 from its dumping position to its load-receiving position.

Stationary, spaced cams 2|8 are carried by each of the rails |74 and have inclined upper surfaces 2li?L arranged to be engaged by the trunnions |535 of the buckets |92 and |133 to effect elevation of said trunnions to a position above the upper ends of the weigher yoke |7 as the buckets are successively moved into loading position. It will be understood, of course, that during a weighing operation, the trunnions |55 of one bucket are disposed between the adjacent ends of the cams 2 8 and the weight of the bucket is supported solely by the yoke |97 and not by the carriage |93. The vertical movement of the trunnions |05 relative to the carriage H33, as either of the buckets |62 and |32 is elevated by the cams 2|8, is permitted by the open vertical slots |55, previously referred to, formed in the side walls of said carriage.

It is, of course, necessary to lift the loaded bucket off the weigher yoke |57 before the carriage |53 can be transferred, and such lifting is accomplished by means of an elevating cam 2|9 (Figs. 8 and 11), mounted upon the shaft |97 adjacent the cam |95. A roller 220 engages the periphery of the cam 2|9 and is secured to the asador-a lower end of a vertically movable bar 22|. The lower end of the bar 22| is slidably received in a groove 222 formed in the side plate ld. One end of an arm 223 is pivotally connected by a pin 221i with the bar 22| and the opposite end of said arm is xed to one end `of a shaft 225. rihe shaft 225 extends transversely between the side plates It@ and'one end of an arm 22s (Fig. 8) is secured to the opposite end of said shaft, as indicated by the dct-and-dash lines. r.The opposite end of the arm 22e is pivotally connected by a pin 22? to the lower end of a second vertically movable bar 228 which rides in a groove 222a formed in the adjacent side plate |85. The bars 22| and 223 are aligned with the yoke le? and are slidably mounted in grooves 229 formed in the brackets |78. The bars 22| and 228 include offset ends 23B, which are located between the vertical arms of the yoke |31 and the side walls of the carriage ISB. The upper ends of the elevating bars 225 and 228 are guided for vertical movement by the reception of the offset ends 23d thereof in grooves 23l (see Figs. ll and 12) formed in the adjacent faces of the stationary cams 2id.

The upper ends of the elevating bars 22| and 22B are positioned directly below the trunnions |35 of the weighing bucket being loaded and, when retracted, are spaced from said trunnions a greater distance than that through which the yoke it? moves downwardly during the loading of the bucket and the making of the desired weight. Hence, the bars 223 and 22s do not in any way interfere with the weighing operation.

The elevating bars 22| and 22d are retracted as permitted by the cam 2 i9 and maintained in their retracted position by a tension spring 23 one end of which spring is connected to a pin on the arm 233 and the other end of which is connected to a pin 231i mounted on one of the side f plates In the operation of the machine, and as previously described, after the desired exact weight has been made, the circuit to the solenoid iii-l is closed b y the mercury switch i-ill-iii land said solenoid is energized to release the driven element ld of the one-revolution clutch lil-, whereupon the shaft |52 eifects a single turn rotation of the shaft IS7 (through intermediate mechanism, not shown) and while the cam i is actuating the yoke iES and the baiiie plate le? and lola to their closed position, the cam 2id is simultaneously effecting raising of the elevating bars 22i and 228 to lift the loaded bucket off the yoke it? to an elevation above the highest portion of the stationary cam surfaces 258e.'

The crank 2|? is simultaneously actuated by means also driven by the shaft E52 'associated with the one-revolution clutch, as previously stated, to effect shifting of the carriage its to effec-t dumping of the. loaded bucket and to position the trunnions |65 of an empty bucket in alignment vith the bars 22! and 22e and the yoke le?.

it will b e understood that the stationary 2 lil are engaged by the trunnions |55 of the loaded bucket and as the carriage H33 moves said bucket down one pair ofthe inclined cam surfaces 258e, the loaded bucket lis lowered in the carriage slots lat. On the other hand, as the carriage itl! moves the empty bucket toward loading position, its trunnions ride up the, other pair of inclined cam surfaces 2*!8l to effect elevation of the -trunnions of said empty bucket to a position above the ends of the elevating bars 22| and 223. After the trunnions |55 have been positioned upon the upper ends of the eleva-ting `bars 22| and 228, the further rotation of the cam 2 |$l allows the spring 232 to retract said bars to Ithereby gently lower the trunnions into engagement with the upper ends of the yoke |61 so that the weight 0f the bucket is transferred to said yoke without jarring. Rotation of the cam |95, meanwhile, actuates the yoke |33 to move the baiiie plates |5'i and |57@ to open position, thereby allowing the material deposited in the hopper |58, while the bucket elevating and shifting operations were occurring, to drop into the empty weighing bucket.

The operation of the present machine vhas been variously described in connection with the operation of the component parts thereof, and it is, therefore, believed unnecessary to include a complete resume of Ithe entire operation of the machine inasmuch as it would be superiluous.

It will be apparent from the foregoing that the weighing mechanism, the bulk and dribble feed vibrators and the feed control chute are all so correlated as to automatically provide for successive, accurate and rapid weighing operations. it will also be understood that the weighed material discharged successively from the respective loaded weighing buckets is preferably deposited in a chute (not shown) arranged so as to effect lling of successive receptacles.

ligs. 13 to 15 diagrammatically illustrate a modified form of automatic weighing machine in which the operation of the dribble feed trough 9U is intermittent instead of continuous, and wherein the temporary hopper-forming baiiies |51 and wie are omitted; and the carriage |523 with its two buckets |62 and |95 are replaced by a single bucket and operating mechanism for automatically elevating and dumping the same after the desired exact weight of material has been deposited therein.

In Fig. 13, the parts corresponding to those already described are identified by the same reference numerals and the description thereof will not be repeated. However, the bulk feed control switch [i8 and the mercury switch I4 l-llifl-M controlling the one-revolution clutch |5| are connected in circuits differing from those previously described, and these will vbe fully discussed hereinafter. The single bucket of the modified machine is identified by the numeral leila and is adapted to cause the weigher yoke lll? and rod |99 to move downwardly in the same manner as the buckets m2 and ltd during the weight-making portion of the cycle. The bucket Illia has an elongated, upright trunnion m5@ at each end thereof. The lower end of each of the trunnions ita is rounded at Iil'o and rests upon the upper end of one of the arms of the yoke it?, and the upper end of each trunnion ieee has a wedge-shaped point |05c provided for a purpose which will be explained later. The mechanism for elevating the bucket 92a after the full weight has been made, and for thereafter dumping said bucket is diagraminatically shown in Figs. 14 and 15.

One side of the normally open bulk feed control switch ||8 is connected with one side of the bulk feed vibrator 9'6 by a wire |23 and the other side of said vibrator is connected by a wire 12da with one contact o f Aa conventional rectifier ities; and the other side of the switch i8 is oonneoted by a wire la with the arm ile of a conventional rheostat IZS, one end of the coil of said rheostat being connected by a wire |29a to another contact of the rectifier |25e, all in a manner similar to that shown in Fig. 1. Another contact of the rectifier |258 is connected by a wire |3|a with the conductor 13, also as in Fig. l; but the remaining contact is connected by a wire 355 with one contact (not shown) of a normally closed Micro switch 36|. The other contact (not shown) of the switch 38| is connected by a wire 332 to the other conductor 15. Thus, it will be apparent that switches |I8 and 33| must both be closed in order to supply current to the bulk vibrator unit 33, and that the operation of the bulk feed conveyor 93 is interrupted by opening of the switch H3 as the weight of material in the bucket |52a closely approaches the desired weight and causes the rod |33 to move downwardly.

One pool Hifi of the mercury switch is connected by a wire 13a with the conductor 13. The other pool |135, however, is connected with one end of a coil 35x33 of a conventional relay 331i by a wire 35, and the other end of the relay coil 333 is connected by a wire 306 with the other conductor 15. The relay 33!! has two xed contacts 331 and 333, and a movable contact 333, on one end of an armature 3M, which is adapted to engage one or the other of said two fixed contacts. The armature SI is connected by a wire 3! i with the conductor 13. The fixed relay contact 353 is connected by a wire 312 to one end of the coil of the electromagnet |51, which controls the one-revolution clutch |5|, and the other side of said coil is connected by a wire 3|3 with the conductor 15. The other Xed relay contact 351 is connected by a wire S to one contact of a conventional rectifier 133e. The opposite contact of the rectifier |33a is connected by a wire 3.!5 to the wire 333. One side of the dribble feed vibrator 18 is connected by a wire |32a to a third contact of the rectifier |333, and the other side of said vibrator is connected by a wire lede to the arm |35a of a conventional rheostat |33f|l Thus, the dribble feed vibrator 18 will relnain in operation even after the circuit to the bulk feed vibrator 53 has been interrupted by opening of the switch |21, as aforedescribed, provided that the relay 334 is `deenergized and the switch 3G! is closed. However, when the dribble feed conveyor 93 has fed sufficient material to the bucket |32EL to make the desired exact weight, the further downward movement of the rod |33 of the weigher |58 incident thereto will cause the U-shaped Contact iii! to engage the mercury pools ldd and |1515 and complete the circuit to the relay coil 3D3, thereby energizing said coil and causing attraction of the armature 3H! to the core of said coil and moving the contact 369 out of engagement with the Contact 361, thus interrupting the circuit to the dribble feed vibrator 13, whereupon the operation of the dribble feed conveyor 99 ceases.

Actuation of the armature 3io, as above described, moves the contact 339 carried thereby into engagement with the contact 358 so that substantially simultaneous with the interruption of the circuit to the dribble feed vibrator 18, the electromagnet |41 is energized to pull the armature |113 thereof out of the path of the arm Ide of the driven element |53 of the one-revolution clutch !5|. A shaft |525 is connected with the driven clutch element and carries a cam 335 whose periphery is adapted to engage with a roller 3|1 on the operating arm of the normally closed switch 30|. The cam 3|5 is designed so that it effects opening of the switch 30| during lthe first few degrees of revolution thereof following the tripping of the one-revolution clutch 15|. The opening of the switch 33| precludes the flow of current to the rectifiers |252- and |33a so that the bulk and dribble feed vibrators 93 and 18, respectively, are forced to remain inactive, even after the bulk feed control switch HS has been allowed to close and the opening of the mercury switch l l-Il-l has deenergized the relay 385 and also deenergized the electromagnet |31, as an incident to the upward movement of the rod |03 during the lifting of the loaded bucket from the yoke |31, all as will appear more fully hereinafter.

The mechanism for lifting the loaded bucket |32a from the yoke |51 and for effecting dumping of said bucket and the return thereof to said yoke includes a face cam 3io mounted upon the shaft |52a (Fig. 14) and provided with a groove Sie. A roller 325 is received in the cam groove 319 and is rotatably mounted upon one end of an arm 32|, the other end of said arm being secured to a shaft 322 rockably supported in bearings, not shown. The shaft 322 has a pair of arms 323 secured thereto, only one of Which is shown in the drawings, it being understood that one arm 323 and the mechanism associated therewith is duplicated at each end of the bucket IEP. One end of a link 324.1 is pivotally connected by a, pin 323 with the arm 323, and the opposite end of said link is pivotally connected by a pin 323 to a lifting nger 321. The lifting finger 321 is pivotally mounted at one end thereof upon an arm 323 by a pin 329 normally disposed above the pin 326. The other or free end of the lifting finger 32'! has the upper surface thereof provided with a semicircular notch 330 adaptedto engage with the rounded end ib of one of the trunnions Hia. rihe arm S23 is pivotally mounted by a pin 33| upon the upper end of a bracket 332. A block 333 is carried by the arm 328 and has a recess 334igenerally coniplemental to the Wedge-pointed end |35c of the trunnion |G5e. One of the trunnions 35 and the bucket |32a are shown in dotand-dash lines in Fig. 14, in the position they assume during a weighing operation, the lifting linger 32"! being shown retracted and Vclear of its associated trunnion |53, The bracket 33?. carries a pad 335 adapted to be engaged by one side of the arm 32S when the lifting finger 321 is in its retracted position. A tension spring 335 has one end thereof connected with the free end of the lifting finger 321 and its other end connected with the arm 323 and continuously tending to pull said lifting finger toward the block 333.

It will be understood that when the bucket |62a is supported upon the weigher yoke |31, as shown in Fig. 13, each of the trunnions H35a assumes the floating position shown Yin dot-anddash lines in Fig. 1li, between a lifting finger 321 and a block 333. Upon tripping of the one-revolution clutch |5|, after making the exa-ct Weight as aforedescribed, the shaft |52a is driven through one revolution and the cam 3|8 is rotated, whereupon the cam groove 3|@ acting on the roller 32E causes the arm 32| to rock the shaft 322, with the result Vthat the upper end of the arm 323 is moved toward the right, as viewed in Fig. 14, thereby causing the p-arts to assume the position shown in Fig. 15 to eect raising of the bucket |02P- from the yoke |51 and dumping of the weighed material from said bucket. Thus, it will be apparent that as the arm 323 is turned in a clockwise direction, the link 324 will cause the lifting finger 321 to rotate counterclockwise about its pivot pin 329 and engage the notch 338 with the rounded end |85b of the trunnion |058, raising the loaded bucket |12a and forcing the pointed end |95c of said trunnion into engagement with the inverted V-shaped portion of the recess 334, the sloping walls of which portion cause the trunnion |85au to center itself in the block 333. While the foregoing is occurring, the bucket |82a is, of course, being lifted off the yoke |91 so that the rod |89 is Dermitted to rise and successively open the switch |4||44|45 to deenergize the relay 334 controlling the circuit to the dribble feed vibrator 18 and closing the bulk feed vibrator control switch IIB. However, the cam 3|6 is now acting on the roller 3|1 of the switch 38| and maintaining the circuits to the vibrator units 18 and 96 open, so that no material can be fed thereby at this time. Eventually, each trunnion |83`a is clamped between a block 333 and a lifting finger 321 through the tension of the springs 336, and the arms 328 are turned about their pivots 33 to move the bucket |82a to its dumping position indicated by dot-and-dash lines in Fig. 15. Thereafter, the direction of travel of the arm 323 is reversed by the cam 3|8 and the empty bucket |02EL is righted and its trunnions |85a returned into engagement with the upper ends of the arms of the yoke |91. After the bucket is thus returned, the cam SIG allows `the switch 38| to close and the circuits to the bulk and dribble feed vibrators are restored and they simultaneously start to feed material into the empty bucket |02EL to start a new weighing cycle. rf he cam 3|8 cornes to rest with the lifting fingers 321 fully retracted against the tension of the springs 336, so as not to interfere with the downward movement of the bucket |82a as the material to be weighed is fed thereto by the bulk and dribble feed conveyors 93 and 98, respectively. The cam 3|6, of course, comes to rest in a position permitting the switch 30| to remain closed until the one-revolution clutch 5| is again tripped.

The automatic weighing machine shown in Figs. 13 to 15 is, of course, adapted to be fed by a feed conveyor such as shown in Fig. 1 and, in fact, the automatic feed control chute 44 has been shown in Fig. 13 for supplying material to the hopper 63.

It will be understood that various changes may be made in the arrangement and details of the various mechanisms and circuits disclosed herein, without departing from the spirit of the invention or the scope of the annexed claims.

I claim:

1. A feeding device for weighing machines, comprising: a trough-shaped bulk feed conveyor; and a dribble feed conveyor, said dribble feed conveyor being disposed above said bulk feed conveyor to overlie the same and being of less width and capacity than said bulk feed conveyor and converging in lateral dimension and capacity toward its discharge end, the lateral edges of said dribble feed conveyor being substantially inward of corresponding edges of said bulk feed conveyor whereby excess material being conveyed by said dribble feed conveyor can overflow onto said bulk feed conveyor before it reaches the discharge end of said dribble feed conveyor and separate means for actuating each of said conveyors independently of the other.

2. A feeding device for weighing machines, comprising: a bulk feed trough; separate means for vibrating said bulk feed trough; a dribble feed trough; and means for vibrating said dribble feed trough, said dribble feed trough being disposed above and overlying said bulk feed trough and being relatively shallow and of less width than and within the lateral boundaries thereof, said bulk feed trough and also converging in dimension and capacity toward its discharge end so that excess material in said dribble feed trough can feed over the sides thereof onto said bulk feed trough before it reaches the discharge end of said dribble feed trough and means for simultaneously feeding material to both said troughs.

3. A feeding device for weighing machines, comprising: a first Avibra-tor unit; a bulk feed trough of relatively large capacity mounted upon said first vibrator unit; a second vibrator unit disposed in tandem relation to said first vibrator unit, a hopper .mounted upon said second vibrator unit, said hopper including a bottom wall and side walls; a dribble feed trough of relatively small capacity carried by said bottom wall of said hopper, said dribble feed trough being of less width than said hopper and forming a continuation of said hopper substantially centrally overlying said bulk feed trough, said dribble feed trough and at least the adjacent end of said bottom wall overlying said bulk feed trough in vertically spaced relation thereto, whereby said hopper is adapted to simultaneously feed material to said dribble and bulk feed troughs, said dribble feed trough having its discharge end in position to discharge material beyond but adjacent the discharge end of said bulk feed trough.

4. A feeding `device as defined in claim 3 wherein said dribble feed trough is arranged to substantially centrally overlie said bulk feed trough with its discharge end and receiving end vertically spaced above corresponding portions of said bulk feed trough, said hopper being at the receiving ends of said troughs and arranged to deliver a stream of material downwardly whereby part of said stream enters said dribble feed trough and the rest of said stream drops therepast into said bulk feed trough.

LUTHER W. ALDRIDGE.

REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 1,120,299 Fleming Dec. 8, 1914 1,170,077 Lawry Feb. 1, 1916 1,259,524 Kelly Mar. 19, 1918 1,322,469 Ross Nov. 18, 1919 2,071,443 Weckerly Feb. 23, 1937 2,101,561 Rapp Dec. 7, 1937 2,139,903 Mason et al Dec. 13, 1938 2,258,182 Howard Oct. 7, 1941 2,266,905 Rapp Dec. 23, 1941 2,270,083 Rapp Jan. 13, 1942 2,332,600 Rapp Oct. 26, 1943 2,333,338 Rapp Nov. 2, 1943 2,333,435 Muskat Nov. 2, 1943 2,834,368 Wolf Nov. 16, 1943 2,342,116 Broekhuysen Feb. l22, 1944 2,352,114 Muskat June 20, 1944 2,365,978 Strain Dec. 26, 1944 2,466,386 Curioni Apr. 5, 1949 

